Synchronous input/output commands writing to multiple targets

ABSTRACT

Aspects include communicating synchronous input/output (I/O) commands between an operating system and a recipient. Communicating synchronous I/O commands includes issuing a first synchronous I/O command with a first initiation bit set, where the first synchronous I/O command cause a first mailbox command to be initiated by the recipient with respect to a first storage control unit. Further, communicating synchronous I/O commands issuing a second synchronous I/O command with a second initiation bit set, where the second synchronous I/O command causes a second mailbox command to be initiated by the recipient with respect to at least one subsequent storage control unit. Communicating synchronous I/O commands also includes issuing a third synchronous I/O command with a first completion bit set in response to the first mailbox command being initiated and issuing a fourth synchronous I/O command with a second completion bit set in response to the first mailbox command being initiated.

DOMESTIC PRIORITY

This application is a continuation of U.S. application Ser. No. 14/872,914, filed on Oct. 1, 2015, the disclosure of which is incorporated by reference herein in its entirety.

BACKGROUND

The disclosure relates generally to synchronous input (I/O) commands writing to multiple targets, and more specifically, to synchronous I/O commands to one or more targets that allow an operating system to independently request a command to be initiated and return control before waiting for a completion to occur.

In general, the technical field discussed herein includes communications between servers and storage control units over a storage area network involving multiple switches and multiple layers of a protocol stack. Contemporary implementations of these communications between servers and storage control units include asynchronous access operations by operating systems within the storage area network. Asynchronous access operations require queues and schedulers for initiating the requests, along with interruptions for any associated context switch for processing a completion status. These queues, schedulers, and interruptions amount to asynchronous overhead that adds significant latency and processing delays across the storage area network.

Storage Area Networks (SANs), as described by the Storage Networking Industry Association (SNIA), are high performance networks that enable storage devices and computer systems to communicate with each other. In large enterprises, multiple computer systems or servers have access to multiple storage control units within the SAN. Typical connections between the servers and control units use technologies such as Ethernet or Fibre-Channel, with the associated switches, I/O adapters, device drivers and multiple layers of a protocol stack. Fibre-channel, for example, as defined by the INCITS T11 Committee, defines physical and link layers FC0, FC1, FC2 and FC-4 transport layers such as the Fibre Channel Protocol (FCP) for SCSI and FC-SB-3 for Fibre Connectivity (FICON). There are many examples of synchronous and asynchronous I/O access methods, each with their own advantages and disadvantages. Synchronous I/O causes a software thread to be blocked while waiting for the I/O to complete, but avoids context switches and interrupts. This works well when the I/O is locally attached with minimal access latency, but as access times increase, the non-productive processor overhead of waiting for the I/O to complete becomes unacceptable for large multi-processing servers. The current state of the art for server access to SAN storage, with its associated protocol over-head, is to use asynchronous I/O access methods. The large variation in access times, and even the minimum access times, of SAN storage with today's protocols such as Fibre-Channel, make synchronous I/O access unacceptable.

SUMMARY

Embodiments include a method for communicating synchronous input/output (I/O) commands between an operating system and a recipient. Communicating synchronous I/O commands includes issuing a first synchronous I/O command with a first initiation bit set, where the first synchronous I/O command cause a first mailbox command to be initiated by the recipient with respect to a first storage control unit. Further, communicating synchronous I/O commands issuing a second synchronous I/O command with a second initiation bit set, where the second synchronous I/O command causes a second mailbox command to be initiated by the recipient with respect to at least one subsequent storage control unit. Communicating synchronous I/O commands also includes issuing a third synchronous I/O command with a first completion bit set in response to the first mailbox command being initiated and issuing a fourth synchronous I/O command with a second completion bit set in response to the first mailbox command being initiated. This can provide the ability to reclaim shared resources if the operating system does not request the completion in a timely manner, such as when a logical partition (LPAR) is not running, without the complexity of background tasks monitoring the shared resources.

Methods can also include where the first and second mailbox commands respectively cause data transfers to the first and the at least one subsequent storage control units to occur in parallel. This can provide the ability to reclaim shared resources.

Methods can also include where the recipient is firmware of the processor. This can provide the ability to reclaim shared resources.

Methods can also include receiving, by the operating system from the recipient, a synchronous I/O complete command in response to the third synchronous I/O command. This can provide the ability to reclaim shared resources.

Methods can also include where the synchronous I/O complete command identifies that a data transfer corresponding to the first mailbox command is complete. This can provide the ability to reclaim shared resources.

Methods can also include receiving, by the operating system from the recipient, a synchronous I/O complete command in response to the fourth synchronous I/O command. This can provide the ability to reclaim shared resources.

Methods can also include where the synchronous I/O complete command identifies that a data transfer corresponding to the second mailbox command is complete. This can provide the ability to reclaim shared resources.

Additional embodiments include systems and computer program products to implement the above methods.

Additional features and advantages are realized through the techniques of the present invention. Other embodiments and aspects of the invention are described in detail herein and are considered a part of the claimed invention. For a better understanding of the invention with the advantages and the features, refer to the description and to the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter which is regarded as the invention is particularly pointed out and distinctly claimed in the claims at the conclusion of the specification. The forgoing and other features, and advantages of the invention are apparent from the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 illustrates a communication schematic comparing synchronous input/output (I/O) and traditional I/O in accordance with an embodiment;

FIG. 2 illustrates a block diagram of a system for performing synchronous I/O in accordance with an embodiment;

FIG. 3 illustrates a block diagram of an environment including a synchronous I/O link interface in accordance with an embodiment;

FIG. 4 illustrates a block diagram of an environment for performing synchronous I/O with respect to a mailbox command and read operation in accordance with an embodiment;

FIG. 5 illustrates a block diagram of an environment for performing synchronous I/O with respect to a write operation in accordance with an embodiment;

FIG. 6 illustrates a block diagram of an environment performing synchronous I/O with respect to a status operation in accordance with an embodiment;

FIG. 7 illustrates a process flow of a synchronous system with respect to early responses of synchronous I/O commands in accordance with an embodiment;

FIG. 8 illustrates an operational example of a synchronous system with respect to early responses of synchronous I/O commands in accordance with an embodiment;

FIG. 9 illustrates another operational example of a synchronous system with respect to early responses of synchronous I/O commands in accordance with an embodiment;

FIG. 10 illustrates another operational example of a synchronous system with respect to early responses of synchronous I/O commands in accordance with an embodiment;

FIG. 11 illustrates a process flow of a synchronous system with respect to sending synchronous I/O commands to multiple targets in accordance with an embodiment;

FIG. 12 illustrates an operational example of a synchronous system with respect to sending synchronous I/O commands to multiple targets in accordance with an embodiment; and

FIG. 13 illustrates a processing system in accordance with an embodiment of the present invention.

DETAILED DESCRIPTION

In view of the above, embodiments of the present invention disclosed herein may include a synchronous system, method, and/or computer program product (herein synchronous system) that executes synchronous input (I/O) commands writing to multiple targets. More specifically, the synchronous system executes synchronous I/O commands to one or more targets that allow an operating system to independently request a command to be initiated and return control before waiting for a completion to occur.

For instance, the synchronous I/O command includes “initiation” and “completion” bits (among other bits) that identify/indicate a type of request. In turn, the synchronous system is configured to reclaim shared resources if the operating system does not request the completion in a timely manner, such as when a logical partition (LPAR) is not running, without the complexity of background tasks monitoring the shared resources. Additionally, the synchronous system performs synchronous I/O while also preserving an operability of writing to multiple targets for data replication, along with multiple target selection and exchange.

Embodiments described herein include a new synchronous input/output (I/O) central processing unit (CPU) instruction or command that allows both the synchronous execution of read and write I/O operations, or the initiation of an I/O operation and subsequent synchronous test for completion. In embodiments, a synchronous low latency protocol running over an interface link such as peripheral component interconnect express (PCIe) is utilized to communicate directly between a processor (also referred to herein as a server) and a storage subsystem. The storage subsystem receives mailbox commands, delivered from the CPU over the PCIe link, that request the synchronous execution of read/write commands. For a read command, if the data is not already in the control unit cache the synchronous command ends unsuccessfully. The control unit can initiate processing to asynchronously read the data into the control unit cache so that it can quickly be read via traditional I/O processing. If the data was in the cache, it can be transferred to the host memory and the synchronous I/O CPU instruction completes successfully. Write operations can transfer data from host memory to the control unit cache of one or more nodes within the control unit.

Embodiments of synchronous I/O described herein when compared to traditional I/O can be utilized to eliminate the overhead associated with a dispatcher, improve transactional latency, preserve contents of L1 and L2 cache by eliminating a context switch, and can reduce lock contention on data by reducing latency.

Described herein is a new dynamic I/O paradigm for storage that can perform both synchronous and asynchronous (or traditional) processing from the application/middleware point of view. When applied to middleware, such as DB2® from IBM®, this new paradigm can result in faster performance. Current versions of DB2 can only have one I/O operation writing to the log at any one time. This single threaded process is highly dependent on the latency of these log write commands for the total throughput that can be accommodated for processing transactions. Embodiments of the synchronous I/O paradigm described herein can reduce the amount of time that it takes to write to the log. Note, that multi-write technology (e.g., zHyperWrite® technology produced by IBM) provides a way of eliminating the latency required by synchronous replication of data. The combination of embodiments described herein with the use of multi-write technology can provide the ability to maintain continuous availability with multi-switch technology (e.g., HyperSwap technology produced by IBM) while getting the benefits of synchronous I/O.

The workloads that run on the z/OS® (an OS from IBM) can typically see very high cache hit ratios (e.g., 90 percent) for read operations. This means that a high percent of the time the data is found in a dynamic random access memory (DRAM) cache in the storage subsystem (e.g., a persistent storage control unit), resulting in reduced I/O service times. These high cache hit ratios can be the result of a long tradition of close integration of the I/O stack from the applications ability to pass cache hints on I/O operations through optimized caching algorithms in the storage subsystem. When the data required for a read request is in DRAM in the storage subsystem it is amenable to being transferred to the host with the new synchronous I/O paradigm. If a cache miss occurs, the storage subsystem can initiate the process to bring the data into cache but synchronously notify the host to execute the I/O operation using the traditional asynchronous model.

Utilizing embodiments described herein to avoid the un-dispatching and re-dispatching of critical applications and middleware, can lead to a reduction in OS overhead and eliminate the L1 and L2 cache damage that can occur when a context switch occurs for a different application. Reducing the L1 and L2 cache damage and re-dispatching of work can lead to a significant reduction in CPU cost.

When embodiments are applied to DB2 executing on a z/OS platform, utilizing embodiments to accelerate read I/O and data base logging can reduce DB2 transactional latency and accelerate transaction processing on the z/OS platform.

In addition, improving database log throughput can reduce cost by requiring fewer data sharing instances (LPARs, I/O connections, log devices) to achieve the work load requirements. It can also avoid forcing clients to re-engineer the workloads in order to avoid hitting constraints.

Turning now to FIG. 1, communication schematics 100 of a traditional I/O and a synchronous I/O when updating data stored on a peripheral storage device are generally shown in accordance with embodiments. As shown on the right side of FIG. 1, performing traditional I/O operations includes receiving a unit of work request 124 at an operating system (OS) 122 in a logical partition (LPAR). The unit of work can be submitted, for example, from an application or middleware that is requesting an I/O operation. As used herein the term “unit of work” refers to dispatchable tasks or threads.

In response to receiving the unit of work request, the OS 122 performs the processing shown in block 104 to request a data record. This processing includes scheduling an I/O request by placing the I/O request on a queue for the persistent storage control unit (CU) 102 that contains the requested data record 104, and then un-dispatching the unit of work. Alternatively, the application (or middleware) can receive control back after the I/O request is scheduled to possibly perform other processing, but eventually the application (or middleware) relinquishes control of the processor to allow other units of work to be dispatched and the application (or middleware) waits for the I/O to complete and to be notified when the data transfer has completed with or without errors.

When the persistent storage control unit (SCU) 102 that contains the data record 104 is available for use and conditions permit, the I/O request is started by the OS issuing a start sub-channel instruction or other instruction appropriate for the I/O architecture. The channel subsystem validates the I/O request, places the request on a queue, selects a channel (link) to the persistent SCU 102, and when conditions permit begins execution. The I/O request is sent to a persistent SCU 102, and the persistent SCU 102 reads the requested data record from a storage device(s) of the persistent SCU 102. The read data record along with a completion status message is sent from the persistent SCU 102 to the OS 122. Once the completion status message (e.g., via an I/O interrupt message) is received by the OS 122, the OS 122 requests that the unit of work be re-dispatched by adding the unit of work to the dispatch queue. This includes re-dispatching the LPAR to process the interrupt and retrieving, by the I/O supervisor in the OS, the status and scheduling the application (or middleware) to resume processing. When the unit of work reaches the top of the dispatch queue, the unit of work is re-dispatched.

Still referring to the traditional I/O, once the data record is received by the OS 122, the OS 122 performs the processing in block 106 to update the data record that was received from the persistent SCU 102. At block 108, the updated data record is written to the persistent SCU 102. As shown in FIG. 1, this includes the OS 122 scheduling an I/O request and then un-dispatching the instruction. The I/O request is sent to a persistent SCU 102, and the persistent SCU 102 writes the data record to a storage device(s) of the persistent SCU 102. A completion status message (e.g., an interruption message) is sent from the persistent SCU 102 to the OS 122. Once the completion status message is received by the OS 122, the OS 122 requests that the unit of work be re-dispatched by adding the unit of work to the dispatch queue. When the unit of work reaches the top of the dispatch queue, the unit of work is re-dispatched. At this point, the unit of work is complete. As shown in FIG. 1, the OS 122 can perform other tasks, or multi-task, while waiting for the I/O request to be serviced by the persistent SCU 102.

The traditional I/O process is contrasted with a synchronous I/O process. As shown in FIG. 1, performing a synchronous I/O includes receiving a unit of work request at the OS 122. In response to receiving the unit of work request, the OS 122 performs the processing shown in block 114 which includes synchronously requesting a data record from the persistent SCU 112 and waiting until the requested data record is received from the persistent SCU 112. Once the data record is received by the OS 122, the OS 122 performs the processing in block 116 to update the data record. At block 118, the updated data record is synchronously written to the persistent SCU 112. A synchronous status message is sent from the persistent SCU 112 to the OS 122 to indicate the data has been successfully written. At this point, the unit of work is complete. As shown in FIG. 1, the OS 122 is waiting for the I/O request to be serviced by the persistent SCU 112 and is not performing other tasks, or multi-tasking, while waiting for the I/O request to be serviced. Thus, in an embodiment, the unit of work remains active (i.e., it is not un-dispatched and re-dispatched) until the OS is notified that the I/O request is completed (e.g., data has been read from persistent SCU, data has been written to persistent SCU, error condition has been detected, etc.).

Thus, as shown in FIG. 1, synchronous I/O provides an interface between a server and a persistent SCU that has sufficiently low overhead to allow an OS to synchronously read or write one or more data records. In addition to the low overhead protocol of the link, an OS executing on the server can avoid the scheduling and interruption overhead by using a synchronous command to read or write one or more data records. Thus, embodiments of synchronous I/O as described herein when compared to traditional I/O not only reduce the wait time for receiving data from a persistent SCU, they also eliminate steps taken by a server to service the I/O request. Steps that are eliminated can include the un-dispatching and re-dispatching of a unit of work both when a request to read data is sent to the persistent SCU and when a request to write data is sent to the persistent SCU. This also provides benefits in avoiding pollution of the processor cache that would be caused by un-dispatching and re-dispatching of work.

As used herein, the term “persistent storage control unit” or “persistent SCU” refers to a storage area network (SAN) attached storage subsystem with a media that will store data that can be accessed after a power failure. As known in the art, persistent SCUs are utilized to provide secure data storage even in the event of a system failure. Persistent SCUs can also provide backup and replication to avoid data loss. A single persistent SCU is typically attached to a SAN and accessible by multiple processors.

As used herein, the term “synchronous I/O” refers to a CPU synchronous command that is used to read or write one or more data records, such that when the command completes successfully, the one or more data records are guaranteed to have been transferred to or from the persistent storage control unit into host processor memory.

Turning now to FIG. 2, a block diagram of a system 200 (e.g., synchronous system) for performing synchronous I/O is generally shown in accordance with an embodiment. The system 200 shown in FIG. 2 includes one or more application/middleware 210, one or more physical processors 220, and one or more persistent SCUs 230. The application/middleware 210 can include any application software that requires access to data located on the persistent SCU 230 such as, but not limited to a relational database manager 212 (e.g. DB2), an OS 214, a filesystem (e.g., z/OS Distributed File Service System z File System produced by IBM), a hierarchical database manager (e.g. IMS® produced by IBM), or an access method used by applications (e.g. virtual storage access method, queued sequential access method, basic sequential access method). As shown in FIG. 2, the database manager 212 can communicate with an OS 214 to communicate a unit of work request that requires access to the persistent SCU 230. The OS 214 receives the unit of work request and communicates with firmware 224 located on the processor 220 to request a data record from the persistent SCU 230, to receive the data record from the persistent SCU 230, to update the received data record, to request the persistent SCU 230 to write the updated data record, and to receive a confirmation that the updated data recorded was successfully written to the persistent SCU 230. The firmware 224 accepts the synchronous requests from the OS 214 and processes them. Firmware 232 located on the persistent SCU 230 communicates with the firmware 224 located on the processor 220 to service the requests from the processor 220 in a synchronous manner.

As used herein, the term “firmware” refers to privileged code running on the processor that interfaces with the hardware used for the I/O communications; a hypervisor; and/or other OS software.

Embodiments described herein utilize peripheral component interconnect express (PCIe) as an example of a low latency I/O interface that may be implemented by embodiments. Other low latency I/O interfaces, such as, but not limited to Infiniband™ as defined by the InfiniBand Trade Association and zSystems coupling links can also be implemented by embodiments.

Turning now to FIG. 3, a block diagram of an environment 300 including a synchronous I/O link interface 305 is depicted in accordance with an embodiment. As shown in FIG. 3, the environment 300 utilizes the synchronous I/O link interface 305 as an interface between a server (e.g., a system 310) and a persistent SCU (e.g., a persistent SCU 320). The synchronous I/O link interface 305 has sufficiently low latency and protocol overhead to allow an OS of the system 310 to synchronously read or write one or more data records from the persistent SCU 320. In addition to the low protocol overhead of the link, the OS can avoid the overhead associated with scheduling and interrupts by using a synchronous command via the synchronous I/O link interface 305 to read or write one or more data records. The synchronous I/O link interface 305, for example, can be provided as an optical interface based on any PCIe base specification (as defined by the PCI-SIG) using the transaction, data link, and physical layers. The synchronous I/O link interface 305 may further include replay buffers and acknowledgement credits to sustain full bandwidth.

The system 310 is configured to provide at least one synchronous I/O link interface 305 having at least one synchronous I/O link 315 to allow connection to at least one persistent SCU (e.g., persistent SCU 320). It can be appreciated that two or more synchronous I/O links 315 may be required for each connection to a persistent SCU. It can also be appreciated that two or more synchronous I/O links 315 may support switch connections to a persistent SCU. In an exemplary embodiment, where PCIe is utilized, the system 310 comprises a PCIe root complex 330 for the interface link 315, while the persistent SCU 320 comprises a PCIe endpoint 335 for the control unit synchronous I/O interface 305.

Turning now to FIG. 4, a block diagram of an environment 400 for performing synchronous I/O with respect to a mailbox command and read operation is depicted in accordance with an embodiment. As shown in FIG. 4, the environment 400 includes a system 310 (e.g., includes the application/middleware 210 and processor 200 of FIG. 2) and a persistent SCU 320 (e.g., includes persistent CU 230 of FIG. 2). The system 310 includes a LPAR 411 comprising memory locations for a data record 413 and an associated suffix 415 and a status area 421 comprising a device table entry (DTE) 423 and a status field 425. DTE 423 is an example of a data structure used by the firmware to store the mappings, such as, between virtual addresses and physical addresses. Similarly, a function table entry (FTE) is an example of a data structure used by a function table to indicate access to a specified synchronous I/O link. The persistent SCU 320 includes at least one mailbox 440 and a data record 450.

In operation, synchronous I/O commands issued by the OS of the system 310 are processed by the firmware 224 to build a mailbox command 460 that is forwarded to the persistent SCU 320. For example, upon processing a synchronization I/O command for the OS by a firmware of the system 310, the firmware prepares hardware of the system 310 and sends the mailbox command 460 to the persistent SCU 320. The mailbox command 460 is sent to the persistent SCU 320 in one or more memory write operations (e.g., over PCIe, using a PCIe base mailbox address that has been determined during an initialization sequence described below). A plurality of mailboxes can be supported by the persistent SCU 320 for each synchronous I/O link 305. A first mailbox location of the plurality of mailboxes can start at the base mailbox address, with each subsequent mailbox location sequentially located 256-bytes after each other. After the mailbox command 460 is sent, the firmware can poll the status area 421 (e.g., a status field 425) for completion or error responses. In embodiments, the status area 421 is located in privileged memory of the system 310 and is not accessible by the OS executing on the system 310. The status area 421 is accessible by the firmware on the system 310 and the firmware can communicate selected contents (or information related to or based on contents) of the status area 421 to the OS (e.g., via a command response block).

In general, a single mailbox command 460 is issued to each mailbox at a time. A subsequent mailbox command will not issue to a mailbox 440 until a previous mailbox command has completed or an error condition (such as a timeout, when the data is not in cache, error in the command request parameters, etc.) has been detected. Successive mailbox commands for a given mailbox 440 can be identified by a monotonically increasing sequence number. Mailboxes can be selected in any random order. The persistent SCU 320 polls all mailboxes for each synchronous I/O link 305 and can process the commands in one or more mailboxes in any order. In an embodiment, the persistent SCU 320 polls four mailboxes for each synchronous I/O link 305. Receipt of a new mailbox command with an incremented sequence number provides confirmation that the previous command has been completed (either successfully or in error by the system 310). In an embodiment, the sequence number is also used to determine an offset of the status area 421. The mailbox command can be of a format that includes 128-bytes. The mailbox command can be extended by an additional 64-bytes or more in order to transfer additional data records. In an embodiment, a bit in the mailbox command is set to indicate the absence or presence of the additional data records.

The mailbox command can further specify the type of data transfer operations, e.g., via an operation code. Data transfer operations include read data and write data operations. A read operation transfers one or more data records from the persistent SCU 320 to a memory of the system 310. A write operation transfers one or more data records from the memory of the system 310 to the storage persistent SCU 320. In embodiments, data transfer operations can also include requesting that the persistent SCU 320 return its World Wide Node Name (WWNN) to the firmware in the server. In further embodiments, data transfer operations can also request that diagnostic information be gathered and stored in the persistent SCU 320.

In any of the data transfer operations the contents of the mailbox command can be protected using a cyclic redundancy check (CRC) (e.g., a 32 bit CRC). In an embodiment, the mailbox command can be protected by a checksum. In an embodiment, if the persistent SCU 320 detects a checksum error, a response code to indicate the checksum error is returned. Continuing with FIG. 4, a synchronous I/O read data record operation will now be described. For instance, if a mailbox command 460 includes an operation code set to read, the persistent SCU 320 determines if the data record or records 450 are readily available, such that the data transfer can be initiated in a sufficiently small time to allow the read to complete synchronously. If the data record or records 450 are not readily available (or if any errors are detected with this mailbox command 460), a completion status is transferred back to the system 310. If the read data records are readily available, the persistent SCU 320 provides 462 the data record 450.

In an embodiment, the persistent SCU 320 processes the mailbox command 460, fetches the data record 450, provides CRC protection, and transfers/provides the data record 450 over the synchronous I/O link 305. The persistent SCU 320 can provide 462 the data record 450 as sequential memory writes over PCIe, using the PCIe addresses provided in the mailbox command 460. Each data record may require either one or two PCIe addresses for the transfer as specified in the mailbox command 460. For example, if length fields in the mailbox command indicate the data record is to be transferred in a single contiguous PCIe address range, only one starting PCIe address is required for each record, with each successive PCIe memory write using contiguous PCIe addresses. In embodiments, the length fields specify the length in bytes of each data record to be transferred.

The data record 450 can include a data portion and a suffix stored respectively on data record 413 and suffix 415 memory locations of the logical partition 411 after the data record 450 is provided. The data record 413 can be count key data (CKD) or extended count key data (ECKD). The data record 413 can also be utilized under small computer system interface (SCSI) standards, such as SCSI fixed block commands. Regarding the suffix, at the end of each data record 450, an additional 4-bytes can be transferred comprising a 32-bit CRC that has been accumulated for all the data in the data record 450. The metadata of the suffix 415 can be created by an operating system file system used for managing a data efficiently. This can be transferred in the last memory write transaction layer packet along with the last bytes of the data record 450, or in an additional memory write.

In addition, a host bridge of the system 310 performs address translation and protection checks (e.g., on the PCIe address used for the transfers) and provides an indication in the DTE 423 to the firmware of the system 310 when the data read 462 is complete. The host bridge can also validate that the received CRC matches the value accumulated on the data transferred. After the last data record and corresponding CRC have been initiated on the synchronous I/O link 305, the persistent SCU 320 considers this mailbox command 460 complete and must be ready to accept a new command in this mailbox 440.

In an exemplary embodiment, the system 310 will consider the mailbox command 450 complete when all the data records 450 have been completely received and the corresponding CRC has been successfully validated. For example, the firmware performs a check of the status area 421 to determine if the data read 462 was performed without error (e.g., determines if the DTE 423 indicates ‘done’ or ‘error’). If the data read 462 was performed without error and is complete, the firmware then completes the synchronous I/O command. The system 310 will also consider the mailbox command 450 complete if an error is detected during the data read 462 or CRC checking process, error status is received from the persistent SCU 320, or the data read 462 does not complete within the timeout period for the read operation.

Embodiments of the mailbox command can also include a channel image identifier that corresponds to a logical path previously initialized by the establish-logical-path procedure, for example over a fibre-channel interface. If the logical path has not been previously established, a response code corresponding to this condition can be written to the status area 421 to indicate that the logical path was not previously established.

The mailbox command block can also include a persistent SCU image identifier that corresponds to a logical path previously initialized by the establish-logical-path procedure. If the logical path has not been previously established, a response code corresponding to this condition can be written to the status area 421 to indicate that the logical path was not previously established.

The mailbox command block can also include a device address within the logical control unit (e.g., a specific portion of the direct access storage device located in the storage control unit) that indicates the address of the device to which the mailbox command is directed. The device address should be configured to the persistent SCU specified, otherwise the persistent SCU 320 can return a response code (e.g., to the status area 421 in the system 310) to indicate this condition.

The mailbox command block can also include a link token that is negotiated by the channel and the persistent SCU 320 each time the synchronous I/O link is initialized. If the persistent SCU 320 does not recognize the link token, it can return a value to the status area 421 that indicates this condition.

The mailbox command block can also include a WWNN that indicates the WWNN of the persistent SCU to which the command is addressed. In embodiments, it is defined to be the 64-bit IEEE registered name identifier as specified in the T11 Fibre-Channel Framing and Signaling 4 (FC-FS-4) document. If the specified WWNN does not match that of the receiving persistent SCU, then a response code indicating this condition is returned to processor.

The mailbox command block can also include device specific information that is used to specify parameters specific to this command. For example, for enterprise disk attachment when a write or read is specified by the operation code, device specific information can include the prefix channel command. In another example, when the operation code specifies that the command is a diagnostic command, the device specific information can include a timestamp representing the time at which this command was initiated and a reason code.

The mailbox command can also include a record count that specifies the number of records to be transferred by this synchronous I/O command (or mailbox command).

When PCIe is being utilized with a mailbox command that includes multiple 32 bit words, the mailbox command can include one or more PCIe data addresses in the following format: PCIe data address bits 63:32 in word “n” to specify the word-aligned address of the location in memory (e.g., in the processor) where data will be fetched for a write and stored for a read operation; and PCIe data addressing bits 31:2 in word “n+1”. In addition word n+1 can include an end or record bit that can be set to indicate that the last word specified is the last word of the record that is to be read or written.

The mailbox command can also include a mailbox valid bit(s) that indicates whether the mailbox command is valid and whether the entire mailbox command has been received.

In view of the above, a synchronous I/O write data record operation will now be described with respect to FIG. 5 in accordance with an embodiment. As shown in FIG. 5, the environment 500 includes a system 310 and a persistent SCU 320. The system 310 includes a logical partition 511 comprising memory locations for a data record 513 and a suffix 515 and a status area 521 comprising a DTE 523 and a status field 525. The persistent SCU 320 includes at least one mailbox 540 and a data record 550 once written.

In operation, for example, upon processing a synchronization I/O command for the OS by a firmware of the system 310, the firmware prepares hardware of the system 310 and sends the mailbox command 560 to mailbox 540 of the persistent SCU 320. As noted above, a plurality of mailboxes can be supported by the persistent SCU 320 for each synchronous I/O link 305. Further, after the mailbox command 560 is sent, the firmware can poll the status area 521 (e.g., a status field 525) for completion or error responses.

If a mailbox command 560, issued to mailbox 540, includes an operation code set to write, the persistent SCU 320 determines if it is able to accept the transfer of the data record or records 550. If the persistent SCU 320 is not able to accept the transfer (or if any errors are detected with this mailbox command 560), a completion status is transferred back to the system 310. If the persistent SCU 320 is able to accept the transfer, the persistent SCU 320 issues memory read requests 565 for the data.

In an embodiment, the persistent SCU 320 processes the mailbox command 560 and issues a read request 565 over PCIe (using the PCIe addresses provided in the mailbox command 560) to fetch the data including the data record 513 and the suffix 515. In response to the read request 565, the host bridge of the system 310 performs address translation and protection checks on the PCIe addresses used for the transfers.

Further, the system 310 responds with memory read responses 570 to these requests. That is, read responses 570 are provided by the system 310 over the synchronous I/O link 305 to the persistent SCU 320 such that the data record 550 can be written. Each data record may require either one or two PCIe addresses for the transfer as specified in the mailbox command 560. For example, if the length fields in the mailbox command indicate the entire record can be transferred using a single contiguous PCIe address range, only one starting PCIe address is required for each record, with each successive PCIe memory read request using contiguous PCIe addresses. At the end of each data record, the additional 8-bytes will be transferred consisting of the 32-bit CRC that has been accumulated for all the data in the record and optionally an LRC or other protection data that has also been accumulated. The total number of bytes requested for each record can be 8-bytes greater than the length of the record to include the CRC protection bytes and the additional 4-bytes for a longitudinal redundancy check (LRC).

After the data and CRC/LRC protection bytes have been successfully received, the persistent SCU 320 responds by issuing a memory write 572 (e.g., of 8-bytes of data). The persistent SCU 320 considers this mailbox command 560 complete after initiating this status transfer and must be ready to accept a new command in this mailbox 540. The system 310 will consider the mailbox command 560 complete when the status transfer has been received. For example, the firmware performs a check of the status area 521 (e.g., determines if the DTE 523 indicates ‘done’ or ‘error’). The system 310 will also consider the mailbox command 560 complete if an error is detected during the data transfer, error status is received from the persistent SCU 320, or the status is not received within the timeout period for this operation.

FIG. 6 illustrates a block diagram of an environment 600 performing synchronous I/O with respect to a status operation in accordance with an embodiment. The status operation, for example, can be a completion status. As shown in FIG. 6, the environment 600 includes a system 310 and a persistent SCU 320. The system 310 includes a logical partition 611 and a status area 621 comprising one or more status fields 625. The persistent SCU 320 includes at least one mailbox 640.

In response to a status request 670, the completion status (as detected and recorded by the persistent SCU 320) is transferred 672 by the persistent SCU 310 to the system 310. In an embodiment where PCIe is utilized that status is transferred 672 to a 64-bit PCIe address that is offset from a status base address specified during an initialization exchange sequence. The status offset can be calculated as indicated in Equation 1.

Offset=(Node#*4096)+(Mailbox#*1024)+(Sequence#*256)  Equation 1

In embodiments, when the persistent SCU 320 completes a read operation successfully, no status is written after the data transfer. The successful reception of the receive data with valid CRC is sufficient indication that the operation has completed successfully. In embodiments, when the persistent SCU 320 completes a write operation, the status is written 672 after the write data has been successfully received. In embodiments, when the persistent SCU 320 completes a command other than a read operation or a write operation, or it is unable to complete a read or write operation successfully, it transfers 672 status information to the server.

In embodiments, the status information can include a bit(s) that indicates whether the status information is valid or invalid. The system 310 can poll on this bit(s) looking for it to indicate valid status information so that it knows that status information has been written.

The status information can also include an error status indicator that indicates whether the mailbox command completed successfully (e.g., write data was successfully written to the persistent SCU 320) or not (e.g., write of data was not successfully written to the persistent SCU 320). In the event that the mailbox command was not successfully completed, the status information provides additional details about the error that was encountered by the persistent SCU 320.

In the event of an error, the status information can include a record number that specifies the record (if any) to which the status information pertains.

In the event of an error, the status information can include a control unit response code that indicates the reason for the synchronous I/O operation failure. Response codes can include, but are not limited to indications that: device-dependent data (e.g., invalid track) is not valid, see response code qualifier for details; incorrect length (e.g., length of data does not match record length); SCU device address invalid; device-dependent error status presented (e.g., data record not available); logical path not established; persistent SCU synchronous I/O busy; read data not immediately available on persistent SCU; write data space not immediately available on persistent SCU; persistent SCU in recovery; checksum error; invalid operation code; sequence number does not match (e.g., mailbox command dropped); link token does not match (e.g., link re-initialized); WWNN does not match (e.g., link connection changed); and/or invalid length.

In the event of an error, the status information can include a persistent SCU response code qualifier whose value may include either an architected value or a model or device dependent value that further describes the condition specified by the response code.

In the event of an error, the status information can include a WWNN of the persistent SCU returning the status information.

In the event of an error, the status information can include a control unit timestamp that indicates when the status condition was detected.

In the event of an error, the status information can include a diagnostic information identifier that indicates that diagnostic information is available in the persistent SCU and can be uniquely identified by the value in this field.

In the event of an error, the status information can include device specific status.

Turning now to FIG. 7, a process flow 700 of a synchronous system is depicted in accordance with an embodiment. The process flow 700 begins at block 705, where an operating system (e.g., operating system 214) issues a first synchronous I/O command with an initiation bit set. The first synchronous I/O command can be issued to any recipient, such as firmware 224, hypervisor, etc. In response, the recipient sends a mailbox command to a second recipient, such as a persistent storage control unit (e.g., the persistent storage CU 230).

At block 710, the operating system receives control (i.e., control is returned) based on the mailbox command being initiated. The operating system identifies that the mailbox command has been initiated when a synchronous I/O initiated command is received from the recipient.

At block 715, the operating system issues a second synchronous I/O command with a completion bit set. The second synchronous I/O command can be one of multiple subsequent commands. The second synchronous I/O command can also be issued to any recipient, such as firmware 224, hypervisor, etc. The second synchronous I/O command checks or determines whether a data transfer (corresponding to the mailbox command) has completed. This check or determination can occur via the same or different synchronous I/O link, as the synchronous system can utilize different synchronous I/O links for multiple requests to achieve best parallelism of the data transfer.

In view of the above, operational examples of a synchronous system with respect to early responses of synchronous I/O commands will now be described with respect to FIGS. 8-10. In general, with regard to early responses, each synchronous I/O command can support a plurality of records, such as 4 records (e.g., 4 device table entries (DTEs), 4 PCI addresses) with a basic command format and 12 records (12 DTEs, 12 PCIe addresses) with an extended command format. For example, if an extended format command supports up to 12 4K records per synchronous I/O mailbox command, for larger writes, such as up to 512K, the operating system 214 would need to issue multiple synchronous I/O commands sequentially until the 512K transfer is complete.

As shown in each of FIGS. 8-10, an operating system 214 communicates with firmware 224 that further communicates with a persistent storage CU 230. With respect to FIG. 8, an operational example 800 regarding a general synchronous I/O command operation is depicted in accordance with an embodiment.

In FIG. 8, the operating system 214 issues to the firmware 224 a synchronous I/O command (request) with an initiation bit set. The request can be referred to as a synchronous I/O initiate command. In response, at block 805, the firmware 224 sets control parameters in the DTE and FTE indicating that this command has been initiated along with other controls for the synchronous command and sends a mailbox command to the persistent storage CU 230. Once the mailbox command is sent to and received by the persistent storage CU 230, the persistent storage CU 230 can proceed with a corresponding data transfer.

Upon sending the mailbox command, the firmware 224 also communicates a synchronous I/O command (initiated) response to the operating system 214. The initiated response can be referred to as synchronous I/O initiated response. Upon receiving the synchronous I/O initiated response, the operating system 214 identifies that the mailbox command has been sent to the persistent storage CU 230. In turn, the operating system 214 can release a processing thread corresponding to the request.

As the corresponding data transfer occurs on the persistent storage CU 230 and without interaction from the operating system 214, the operating system 214 is unaware of when the data transfer is complete. In turn, at block 815, the operating system 214 can issue other synchronous I/O commands to other control units, on alternate paths to the same control unit, or perform other processing. When the operating system 214 wishes to determine that a previously initiated synchronous I/O command has completed, it re-issues the synchronous I/O command with the completion bit set to request the firmware 224 to determine when the data transfer is complete. As shown in FIG. 8, the operating system 214 issues another synchronous I/O command with a completion bit set (see the resume arrow) to the firmware 224. This resume can be referred to as a synchronous I/O completion command.

In response, at block 825, the firmware 224 polls control structures accessible to the firmware 224 to determine when the data transfer is completed. For example, the firmware 224 polls a status area 521 for a status of the data transfer. When the data transfer is complete, a Status area 421 is updated either by the firmware 224 and its associated hardware or the persistent storage CU 230. In turn, at block 835, the firmware 224 and/or hardware sets the control structures to indicate that the data transfer is complete (e.g., DTE is set to done). Then, at block 845, the firmware 224 issues a synchronous I/O response (see the complete arrow) to inform the operating system 214 that the data transfer (corresponding to the mailbox command) has completed. At block 855, the operating system 214 releases a function handle, which identifies the synchronous I/O link, so that the synchronous I/O link can be reused by that operating system 214. With respect to the function handle, for example, the function handle can be a PCI function handle (PFH) that designates the PCI function (e.g., synchronous I/O link) to which the I/O operation is to be performed). The PFH can be used by the firmware 224 in conjunction with a function table entry (FTE) in a function table to determine whether the operating system 214 can access the synchronous I/O link specified by the PFH. If the specified PFH is not recognized (that is, it is outside of the range of PCI function handles that are supported (e.g., by a z/PCI facility), or the specified PFH is not configured or in standby state for the requesting configuration), then a response code indicating this condition can be returned to the operating system 214 in a command response block.

Turning now to FIG. 9, an operational example 900 regarding a synchronous I/O command operation when a logical partition of the operating system 214 goes offline for a period of time is depicted in accordance with an embodiment.

In FIG. 9, the operating system 214 issues to the firmware 224 a synchronous I/O command (request) with an initiation bit set. In response, at block 905, the firmware 224 sets DTE and FTE and sends a mailbox command to the persistent storage CU 230. Once the mailbox command is sent to and received by the persistent storage CU 230, the persistent storage CU 230 can proceed with a corresponding data transfer. Upon sending the mailbox command, the firmware 224 also communicates a synchronous I/O response (initiated) to the operating system 214. Upon receiving the synchronous I/O initiated response, the operating system 214 releases a processing thread corresponding to the request (e.g., performs an early release that can permit further requests to other control units or to the same control unit via an alternate path.

As indicated above, the logical partition of the operating system 214 that communicated the synchronous I/O initiate command may go offline. In turn, a synchronous I/O completion command cannot be sent. Yet, because a corresponding data transfer occurs on the persistent storage CU 230 without interaction from the operating system 214, it is possible for the corresponding data transfer to complete before the logical partition is back online. In this case, a DMA Data/Status is communicated between the firmware 224 and the persistent storage CU 230. In turn, at block 925, the firmware 224 and/or hardware sets the control structures to indicate that the data transfer is complete (e.g., DTE is set to done).

When the logical partition is back online, the operating system 214 will be unaware of the status of the data transfer. In turn, at block 930, the operating system 214 can issue synchronous I/O commands to request the firmware 224 to determine when the data transfer is complete. As shown in FIG. 9, the operating system 214 issues another synchronous I/O command with a completion bit set (see the resume arrow) to the firmware 224. In response, at block 935, the firmware 224 polls control structures accessible to the firmware 224 to determine when the data transfer is completed. For example, the firmware 224 checks a status of DTE and FTE for a status of the data transfer. Since the data transfer was completed as indicated by the control structures, at block 945, the firmware 224 issues a synchronous I/O response (see the complete arrow) to inform the operating system 214 that the data transfer (corresponding to the mailbox command) has completed. At block 955, the operating system 214 releases a function handle, which identifies the synchronous I/O link, so that the synchronous I/O link can be reused by the operating system 214.

Turning now to FIG. 10, an operational example 1001 regarding two logical partitions of the operating system 214 communicating synchronous I/O commands is depicted in accordance with an embodiment.

In FIG. 10, a first instance (LPAR1) of the operating system 214 issues to the firmware 224 a synchronous I/O command (LPAR1: Request) with an initiation bit set. In response, at block 1005, the firmware 224 sets DTE1 and FTE1 and sends a mailbox command (LPAR1: Mailbox Command) to the persistent storage CU 230. Once the LPAR1: Mailbox Command is sent to and received by the persistent storage CU 230, the persistent storage CU 230 can proceed with a corresponding data transfer. Upon sending the LPAR1: Mailbox Command, the firmware 224 also communicates a synchronous I/O initiated response (LPAR1: Initiated) to LPAR1. Upon receiving the synchronous I/O initiated command, LPAR1 releases a processing thread corresponding to the LPAR1: Request.

With this synchronous I/O command complete, a second portion (LPAR2) of the operating system 214 can sequentially or concurrently on a separate processor issue to the firmware 224 a synchronous I/O command (LPAR2: Request) with an initiation bit set. LPAR2 can operate regardless of the status of LPAR1. For example, as shown in FIG. 10, LPAR2 can operate even if LPAR1 goes offline. Further, even if LPAR1 goes offline, because a data transfer (corresponding to LPAR1: Request) occurs on the persistent storage CU 230 without interaction from LPAR1, the corresponding data transfer can proceed to completion. In this case, an LPAR1: DMA Data/Status is communicated between the firmware 224 and the persistent storage CU 230. In turn, at block 1015, the firmware 224 and/or hardware sets the control structures to indicate that the data transfer is complete (e.g., DTE1 is set to done).

In response to LPAR2: Request, at block 1025, the firmware 224 checks if there are shared mailbox or DTE resources available. If not, DTEs are checked to see if they can be reclaimed, and in this case DTE1 is in such a state. If DTE1 is complete (in this case DTE1 was set to complete in block 1015) then the firmware 224 sets FTE1 to complete. Further, at block 1035, the firmware 224 sets control structures (e.g., DTE1 and FTE2) and sends another mailbox command (LPAR2: Mailbox Command) based on the LPAR2: Request to the persistent storage CU 230. Note that FTE2 can be utilized if a subsequent request is sent and DTE1 is appropriated by the firmware 224. Once the LPAR2: Mailbox Command is sent to and received by the persistent storage CU 230, the persistent storage CU 230 can proceed with a corresponding data transfer. Upon sending the LPAR2: Mailbox Command, the firmware 224 also communicates a synchronous I/O initiated response (LPAR2: Initiated) to LPAR2. Upon receiving the synchronous I/O initiated response, LPAR2 releases a processing thread corresponding to the request (e.g., performs an early release that can permit further requests).

As the data transfer (corresponding to LPAR2: Request) occurs on the persistent storage CU 230 and without interaction from LPAR2, LPAR2 is unaware of when the data transfer is complete. Thus, the data transfer can complete at any time. When the data transfer completes, an LPAR2: DMA Data/Status is communicated between the firmware 224 and the persistent storage CU 230. In turn, at block 1045, the firmware 224 and/or hardware sets the control structures to indicate that the data transfer is complete (e.g., DTE1 is set to done). Note that DTE1 can be set to done, because the control structure FTE1 was set to identity the completion of the data transfer corresponding to LPAR1: Request.

To determine if the data transfer is complete, LPAR2 can issue a synchronous I/O completion command (LPAR2: Resume) to request the firmware 224 to determine when the data transfer is complete. In response to LPAR2: Resume, at block 1055, the firmware 224 checks a status area 421. Since DTE1 was set to done at block 1045, the firmware 224 at block 1065 performs a complete synchronization operation by issuing a synchronous I/O response (LPAR2: Complete) to LPAR2.

Further, when the LPAR1 is back online, the LPAR1 will be unaware of the status of the data transfer. In turn, LPAR1 can issue a synchronous I/O command (LPAR1: Resume). In response, at block 1075, the firmware 224 polls control structures (in this case FTE1, which was set to complete at block 1025). Then, the firmware 224 issues a synchronous I/O response (LPAR1: Complete) to inform LPAR1 the data transfer corresponding to LPAR1: Request is complete.

FIGS. 11-12 respectively depict a process flow and an operational example of a synchronous system with respect to sending synchronous I/O commands to multiple targets in accordance with embodiments. In general, writing to multiple targets (a.k.a. zHyperWrite® as noted above) is capability of software, such as an operating system 214, to replicate data across multiple control units. Synchronous I/O can require replicating data across multiple control units occurs sequentially, where a subsequent data write operation can only begin after a prior data write operation has completed. For example, to perform a first data write operation, software will open a processor thread to issue a unit of work request to a first control unit and keep that processor thread open until the unit of work request is complete. Then, to perform a second data write operation, software will issue another unit of work request to a second control unit. Note that while the first processor thread is kept open, all the work is being performed by the first control unit and thus the first processor thread is occupying resources unnecessarily.

In contrast, the synchronous I/O embodiments herein utilize the synchronous I/O commands to perform multiple data write operations to multiple control units in parallel. Particularly, the synchronous I/O embodiments herein enable the software to launch subsequent synchronous I/O commands without regard to whether prior synchronous I/O commands are complete. Rather, it is sufficient to know that a recipient of a prior synchronous I/O command has communicated a mailbox command to a control unit to launch a subsequent synchronous I/O command. Thus, synchronous I/O commands enable the release of processor threads early (e.g., after mailbox command has been sent, but before the corresponding data transfers are complete).

Turning now to FIG. 11, a process flow 1101 for sending synchronous I/O commands to multiple targets to cause multiple data write operations to occur in parallel is depicted. The process flow 1101 begins at block 1105, where an operating system (e.g., operating system 214) issues a first synchronous I/O command with an initiation bit set. The first synchronous I/O command can be issued to any recipient, such as firmware 224, hypervisor, etc. In response, the recipient sends a first mailbox command to a second recipient, such as a first storage control unit (e.g., the persistent storage CU 230).

At block 1110, the operating system receives control (i.e., control is returned) based on the first mailbox command being initiated. The operating system identifies that the first mailbox command has been initiated when a synchronous I/O initiated response is received from the recipient.

Next, at block 1115, the operating system issues a second synchronous I/O command with an initiation bit set. The second synchronous I/O command can be one of multiple subsequent commands. The second synchronous I/O command can also be issued to any recipient, such as firmware 224, hypervisor, etc. In response, the recipient sends a second mailbox command to a second recipient, such as a second storage control unit (e.g., the persistent storage CU 230) or at least one subsequent storage control unit.

At block 1120, the operating system receives control (i.e., control is returned) based on the second mailbox command being initiated. The operating system identifies that the second mailbox command has been initiated when a synchronous I/O initiated response is received from the recipient.

Then, at block 1125, the operating system issues a third synchronous I/O command with a completion bit set. The third synchronous I/O command can be issued to any recipient, such as firmware 224, hypervisor, etc. The third synchronous I/O command checks or determines whether a data transfer (corresponding to the first mailbox command to the first storage control unit) has completed. The firmware checks the status area 421 associated with the first storage control unit to determine if the data transfer has completed, and when it has it returns the completion response to the operating system.

At block 1120, the operating system issues a fourth synchronous I/O command with a completion bit set. The fourth synchronous I/O command can be issued to any recipient, such as firmware, hypervisor, etc. The fourth synchronous I/O command checks or determines whether a data transfer (corresponding to the second mailbox command) has completed. The firmware checks the status area 421 associated with the second storage control unit to determine if the data transfer has completed, and when it has it returns the completion response to the operating system.

In view of the above, an operational example 1201 will now be described with respect to FIG. 12. As shown in FIG. 12, an operating system 214 communicates with firmware 224 that further communicates with one or more persistent storage CUs 230 (e.g., control unit 1 and control unit 2). Particularly, the operating system 214 issues a synchronous I/O command (request 1) with an initiation bit set to the firmware 224. Request 1 can be referred to as a synchronous I/O initiate command. In response, at block 1205, the firmware 224 sets DTE1 and FTE1 and sends a mailbox command 1 to a control unit 1. Once the mailbox command 1 is sent to and received by the control unit 1, the control unit 1 can proceed with a corresponding data transfer.

Upon sending the mailbox command 1, the firmware 224 also communicates a synchronous I/O command response (initiated 1) to the operating system 214. Initiated 1 can be referred to as synchronous I/O initiated command response. Upon receiving the synchronous I/O initiated command response, the operating system 214 identifies that the mailbox command 1 has been sent to the control unit 1. In turn, the operating system 214 can release a processing thread corresponding request 1.

Next, the operating system 214 issues another synchronous I/O command (request 2) with an initiation bit set to the firmware 224. Request 2 can also be referred to as a synchronous I/O initiate command. In response, at block 1235, the firmware 224 sets DTE2 and FTE2 and sends a mailbox command 2 to a control unit 2. Once the mailbox command 2 is sent to and received by the control unit 2, the control unit 2 can proceed with a corresponding data transfer. Note that the synchronous I/O commands (e.g., request 1 and request 2 and the corresponding mailbox commands 1 and 2) are issued to multiple targets (e.g., control unit 1 and control unit 2) sequentially to allow data transfers to occur in parallel. Further, the operating system 214 can issue multiple synchronous I/O initiate commands to multiple targets, each with its own prefix, security identifier, etc. In this way, a hint can be provided in a prefix that more synchronous I/O mailbox commands may be coming.

Upon sending the mailbox command 2, the firmware 224 also communicates a synchronous I/O command response (initiated 2) to the operating system 214. Initiated 1 can be referred to as synchronous I/O initiated command response. Upon receiving the synchronous I/O initiated command response, the operating system 214 identifies that the mailbox command 2 has been sent to the control unit 2. In turn, the operating system 214 can release a processing thread corresponding to request 2. Note that the firmware 224 architecture can permit a plurality of targets, such as 3 targets with 1 being primary and 2 being secondary or 5 targets with 1 being primary and 4 being secondary. Further, a single descriptor list for a data source can be utilized for each synchronous I/O command request.

As the data transfers occur in parallel on the control units 1, 2 and without interaction from the operating system 214, the operating system 214 is unaware of when the data transfers are complete. In turn, the operating system 214 can issue synchronous I/O commands to determine completion status for each request initiated. As shown in FIG. 12, the operating system 214 issues another synchronous I/O command (resume 1) with a completion bit set to the firmware 224. Resume 1 can be referred to as a synchronous I/O completion command. In response, at block 1245, the firmware 224 checks a status area 421 for a status of the data transfer. If the status is complete, the firmware 224 issues a synchronous I/O command response (complete 1) to inform the operating system 214 that the data transfer (corresponding to the mailbox command 1) has completed.

Similarly, the operating system 214 issues another synchronous I/O command (resume 2) with a completion bit set to the firmware 224. Resume 2 can be referred to as a synchronous I/O completion command. In response, at block 1255, the firmware 224 checks a status area 421 for a status of the data transfer. When the status is complete, the firmware 224 issues a synchronous I/O command response (complete 2) to inform the operating system 214 that the data transfer (corresponding to the mailbox command 2) has completed.

Referring now to FIG. 13, there is shown an embodiment of a processing system 1300 for implementing the teachings herein. In this embodiment, the processing system 1300 has one or more central processing units (processors) 1301 a, 1301 b, 1301 c, etc. (collectively or generically referred to as processor(s) 1301). The processors 1301, also referred to as processing circuits, are coupled via a system bus 1302 to system memory 1303 and various other components. The system memory 1303 can include read only memory (ROM) 1304 and random access memory (RAM) 1305. The ROM 1304 is coupled to system bus 1302 and may include a basic input/output system (BIOS), which controls certain basic functions of the processing system 1300. RAM is read-write memory coupled to system bus 1302 for use by processors 1301.

FIG. 13 further depicts an input/output (I/O) adapter 1306 and a network adapter 1307 coupled to the system bus 1302. I/O adapter 1306 may be a small computer system interface (SCSI) adapter that communicates with a hard disk 1308 and/or tape storage drive 1309 or any other similar component. I/O adapter 1306, hard disk 1308, and tape storage drive 1309 are collectively referred to herein as mass storage 1310. Software 1311 for execution on processing system 1300 may be stored in mass storage 1310. The mass storage 1310 is an example of a tangible storage medium readable by the processors 1301, where the software 1311 is stored as instructions for execution by the processors 1301 to perform a method, such as the process flows above. Network adapter 1307 interconnects system bus 1302 with an outside network 1312 enabling processing system 1300 to communicate with other such systems. A screen (e.g., a display monitor) 1315 is connected to system bus 1302 by display adapter 1316, which may include a graphics controller to improve the performance of graphics intensive applications and a video controller. In one embodiment, adapters 1306, 1307, and 1316 may be connected to one or more I/O buses that are connected to system bus 1302 via an intermediate bus bridge (not shown). Suitable I/O buses for connecting peripheral devices such as hard disk controllers, network adapters, and graphics adapters typically include common protocols, such as the Peripheral Component Interconnect (PCI). Additional input/output devices are shown as connected to system bus 1302 via an interface adapter 1320 and the display adapter 1316. A keyboard 1321, mouse 1322, and speaker 1323 can be interconnected to system bus 1302 via interface adapter 1320, which may include, for example, a Super I/O chip integrating multiple device adapters into a single integrated circuit.

Thus, as configured in FIG. 13, processing system 1305 includes processing capability in the form of processors 1301, and, storage capability including system memory 1303 and mass storage 1310, input means such as keyboard 1321 and mouse 1322, and output capability including speaker 1323 and display 1315. In one embodiment, a portion of system memory 1303 and mass storage 1310 collectively store an operating system, such as the z/OS or AIX operating system from IBM Corporation, to coordinate the functions of the various components shown in FIG. 13.

Technical effects and benefits of the embodiments herein provide advantages over asynchronous/traditional I/O commands by avoiding overhead of interrupt processing and dispatching.

For instance, asynchronous/traditional I/O commands include the disadvantage that while waiting on an I/O operation to complete, a processor executes other productive work, causing overhead for un-dispatch and re-dispatch, context switch overhead with the I/O interrupt and the processor cache content change. In contrast, embodiments herein allows multiple synchronous I/O commands to be initiated, thus allowing multiple synchronous I/O operations to begin, while also allowing additional work to be performed before resuming the command to determine when the I/O operation completes. Further, synchronous I/O commands allow an operating system to issue multiple synchronous I/O commands to multiple targets or transfer multiple records to the same or different targets, to achieve parallelism, and thus improved performance over multiple operations.

In another example, traditional enterprise storage attachments, such as Fiber Connection (FICON) and Fibre Channel Protocol (FCP), have multiple protocol layers that require several hardware, firmware and software levels of processing which cause overhead and add latency. In contrast, the synchronous I/O of embodiments herein eliminates many of these layers, thus improving system efficiency while providing the enterprise qualities of service that includes end-to-end data integrity checking, in-band instrumentation and measurements, work load management and continuous availability with predictable and repeatable high performance.

Embodiments described herein provide SAN attached external persistent storage for synchronous access. In addition, embodiments provide the dynamic switching between synchronous I/O and asynchronous I/O access. Shareable external SAN storage typically will have a mix of short and long running I/O operations which can utilized and benefit from this ability to dynamically switch between the synchronous and asynchronous selection. Embodiments also provide a means for notifying software when the data is not available for synchronous access and the dynamic switching to asynchronous access.

Embodiments described herein provide a low-latency protocol for server to SAN storage communication that allows synchronous I/O access with its inherent advantages of avoiding context switches, interruptions and processor cache pollution, while also providing mechanisms for avoiding processor blocking when access times become too great. Mechanisms are described for dynamic notification and selection of synchronous or asynchronous I/O access.

Thus, embodiments described herein are necessarily rooted in processing system to perform proactive operations for efficiently replicating data across multiple storage subsystems in order to provide continuous availability to overcome problems specifically arising in the realm of traditional I/O and storage subsystem failures.

The embodiments herein may be a system, a method, and/or a computer program product at any possible technical detail level of integration. The computer program product may include a computer readable storage medium (or media) having computer readable program instructions thereon for causing a processor to carry out aspects of the embodiments herein.

The computer readable storage medium can be a tangible device that can retain and store instructions for use by an instruction execution device. The computer readable storage medium may be, for example, but is not limited to, an electronic storage device, a magnetic storage device, an optical storage device, an electromagnetic storage device, a semiconductor storage device, or any suitable combination of the foregoing. A non-exhaustive list of more specific examples of the computer readable storage medium includes the following: a portable computer diskette, a hard disk, a random access memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or Flash memory), a static random access memory (SRAM), a portable compact disc read-only memory (CD-ROM), a digital versatile disk (DVD), a memory stick, a floppy disk, a mechanically encoded device such as punch-cards or raised structures in a groove having instructions recorded thereon, and any suitable combination of the foregoing. A computer readable storage medium, as used herein, is not to be construed as being transitory signals per se, such as radio waves or other freely propagating electromagnetic waves, electromagnetic waves propagating through a waveguide or other transmission media (e.g., light pulses passing through a fiber-optic cable), or electrical signals transmitted through a wire.

Computer readable program instructions described herein can be downloaded to respective computing/processing devices from a computer readable storage medium or to an external computer or external storage device via a network, for example, the Internet, a local area network, a wide area network and/or a wireless network. The network may comprise copper transmission cables, optical transmission fibers, wireless transmission, routers, firewalls, switches, gateway computers and/or edge servers. A network adapter card or network interface in each computing/processing device receives computer readable program instructions from the network and forwards the computer readable program instructions for storage in a computer readable storage medium within the respective computing/processing device.

Computer readable program instructions for carrying out operations of the embodiments herein may be assembler instructions, instruction-set-architecture (ISA) instructions, machine instructions, machine dependent instructions, microcode, firmware instructions, state-setting data, configuration data for integrated circuitry, or either source code or object code written in any combination of one or more programming languages, including an object oriented programming language such as Smalltalk, C++, or the like, and procedural programming languages, such as the “C” programming language or similar programming languages. The computer readable program instructions may execute entirely on the user's computer, partly on the user's computer, as a stand-alone software package, partly on the user's computer and partly on a remote computer or entirely on the remote computer or server. In the latter scenario, the remote computer may be connected to the user's computer through any type of network, including a local area network (LAN) or a wide area network (WAN), or the connection may be made to an external computer (for example, through the Internet using an Internet Service Provider). In some embodiments, electronic circuitry including, for example, programmable logic circuitry, field-programmable gate arrays (FPGA), or programmable logic arrays (PLA) may execute the computer readable program instructions by utilizing state information of the computer readable program instructions to personalize the electronic circuitry, in order to perform aspects of the embodiments herein.

Aspects of the embodiments herein are described herein with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the invention. It will be understood that each block of the flowchart illustrations and/or block diagrams, and combinations of blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer readable program instructions.

These computer readable program instructions may be provided to a processor of a general purpose computer, special purpose computer, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions/acts specified in the flowchart and/or block diagram block or blocks. These computer readable program instructions may also be stored in a computer readable storage medium that can direct a computer, a programmable data processing apparatus, and/or other devices to function in a particular manner, such that the computer readable storage medium having instructions stored therein comprises an article of manufacture including instructions which implement aspects of the function/act specified in the flowchart and/or block diagram block or blocks.

The computer readable program instructions may also be loaded onto a computer, other programmable data processing apparatus, or other device to cause a series of operational steps to be performed on the computer, other programmable apparatus or other device to produce a computer implemented process, such that the instructions which execute on the computer, other programmable apparatus, or other device implement the functions/acts specified in the flowchart and/or block diagram block or blocks.

The flowchart and block diagrams in the Figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods, and computer program products according to various embodiments of the embodiments herein. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of instructions, which comprises one or more executable instructions for implementing the specified logical function(s). In some alternative implementations, the functions noted in the blocks may occur out of the order noted in the Figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems that perform the specified functions or acts or carry out combinations of special purpose hardware and computer instructions.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one more other features, integers, steps, operations, element components, and/or groups thereof.

The descriptions of the various embodiments of the embodiments herein have been presented for purposes of illustration, but are not intended to be exhaustive or limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein was chosen to best explain the principles of the embodiments, the practical application or technical improvement over technologies found in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein. 

1. A method for communicating synchronous input/output (I/O) commands between an operating system and a recipient, the operating system and the recipient executing on a processor coupled to a memory, the method comprising: issuing, by the operating system to the recipient, a first synchronous I/O command with a first initiation bit set, the first synchronous I/O command causing a first mailbox command to be initiated by the recipient with respect to a first storage control unit; receiving control of the first storage control unit from the recipient based on the first mailbox command being initiated; issuing, by the operating system to the recipient, a second synchronous I/O command with a second initiation bit set, the second synchronous I/O command causing a second mailbox command to be initiated by the recipient with respect to at least one subsequent storage control unit; receiving control of the second storage control unit from the recipient based on the second mailbox command being initiated, wherein the first and second mailbox commands respectively cause data transfers to the first and the at least one subsequent storage control units to occur in parallel; issuing, to the recipient, a third synchronous I/O command with a first completion bit set in response to the first mailbox command being initiated; issuing, to the recipient, a fourth synchronous I/O command with a second completion bit set in response to the second mailbox command being initiated, receiving, from the recipient, a first synchronous I/O complete command in response to the third synchronous I/O command; and receiving, from the recipient, a second synchronous I/O complete command in response to the fourth synchronous I/O command.
 2. (canceled)
 3. The method of claim 1, wherein the recipient is firmware of the processor.
 4. (canceled)
 5. The method of claim 1, wherein the first synchronous I/O complete command identifies that a data transfer corresponding to the first mailbox command is complete.
 6. (canceled)
 7. The method of claim 1, wherein the second synchronous I/O complete command identifies that a data transfer corresponding to the second mailbox command is complete. 